The sequence necessary for the infectivity of hop stunt viroid cDNA clones

Analysis of Hop Stunt Viroid Diversity in Grapevine (Vitis vinifera L.) in Slovakia: Coexistence of Two Particular Genetic Groups

The hop stunt viroid (HSVd) is a widespread subviral pathogen infecting a broad spectrum of plant hosts including grapevine (Vitis vinifera L.). Despite its omnipresence in virtually all grapevine growing areas around the world, molecular data characterizing HSVd populations are missing from Slovakia. Analysis of the complete nucleotide sequences of 19 grapevine variants revealed the existence of two genetic HSVd groups in Slovakia (internally named the "6A" and "7A" groups based on the particular stretch of adenines at nucleotide positions 39-44/45, respectively). Despite their sampling at different times in various unrelated vineyards, the 6A and 7A groups are characterized by low intra-group divergence (~0.3 and 0.2%, respectively). On the other hand, inter-group divergence reached 2.2% due to several mutations, seven of which were found to be group-specific and mainly (except for one) located in the region of the pathogenic domain. Interestingly, in addition to their frequent co-existence within the same geographical location, the mixed infection of the 6A and 7A type sequence variants was also unequivocally and repeatedly proven within single grapevine plants. The RNA secondary structure analysis of representative isolates from each of these two genetic groups indicated a potential compensatory explanation of such mutations. These group-specific sites could be pointing towards the evolutionary selection linked to the necessity of the viroid to retain its structural conformational integrity, crucial for its functional biochemical ability to interact with specific grapevine cellular host factors required for HSVd propagation.

Precisely Monomeric Linear RNAs of Viroids Belonging to Pospiviroid and Hostuviroid Genera Are Infectious Regardless of Transcription Initiation Site and 5'-Terminal Structure

Infectious dimeric RNA transcripts are a powerful tool for reverse genetic analyses in viroid studies. However, the construction of dimeric cDNA clones is laborious and time consuming, especially in mutational analyses by in vitro mutagenesis. In this study, we developed a system to synthesize a precisely monomeric linear RNA that could be transcribed in vitro directly from the cDNA clones of four viroid species. The cDNA clones were constructed such that RNA transcription was initiated at the guanine nucleotide of a predicted processing and ligation site in the viroid replication process. Although the transcribed RNAs were considered to possess 5′-triphosphate and 3′-hydroxyl termini, the RNA transcripts were infectious even without in vitro modifications. Additionally, infectivity was detected in the monomeric RNA transcripts, in which transcription was initiated at guanine nucleotides distinct from the predicted processing/ligation site. Moreover, monomeric viroid RNAs bearing 5′-monophosphate, 5′-hydroxyl, or 5′-capped termini were found to be infectious. Northern blot analysis of the pooled total RNA of the plants inoculated with the 5′-terminal modified RNA of potato spindle tuber viroid (PSTVd) indicated that maximum PSTVd accumulation occurred in plants with 5′-monophosphate RNA inoculation, followed by the plants with 5′-triphosphate RNA inoculation. Our system for synthesizing an infectious monomeric linear viroid RNA from a cDNA clone will facilitate mutational analyses by in vitro mutagenesis in viroid research.

Hop stunt viroid: A polyphagous pathogenic RNA that has shed light on viroid-host interactions

TAXONOMY

Hop stunt viroid (HSVd) is the type species of the genus Hostuviroid (family Pospiviroidae). The other species of this genus is Dahlia latent viroid, which presents an identical central conserved region (CCR) but lacks other structural hallmarks present in Hop stunt viroid. HSVd replication occurs in the nucleus through an asymmetric rolling-circle model as in the other members of the family Pospiviroidae, which also includes the genera Pospiviroid, Cocadviroid, Apscaviroid, and Coleoviroid.

PHYSICAL PROPERTIES

Hop stunt viroid consists of a single-stranded, circular RNA of 295-303 nucleotides depending on isolates and sequence variants. The most stable secondary structure is a rod-like or quasi-rod-like conformation with two characteristic domains: a CCR and a terminal conserved hairpin similar to that of cocadviroids. HSVd lacks a terminal conserved region.

HOSTS AND SYMPTOMS

HSVd infects a very broad range of natural hosts and has been reported to be the causal agent of five different diseases (citrus cachexia, cucumber pale fruit, peach and plum apple apricot distortion, and hop stunt). It is distributed worldwide.

TRANSMISSION

HSVd is transmitted mechanically and by seed.

Progress in 50 years of viroid research-Molecular structure, pathogenicity, and host adaptation

Viroids are non-encapsidated, single-stranded, circular RNAs consisting of 246-434 nucleotides. Despite their non-protein-encoding RNA nature, viroids replicate autonomously in host cells. To date, more than 25 diseases in more than 15 crops, including vegetables, fruit trees, and flowers, have been reported. Some are pathogenic but others replicate without eliciting disease. Viroids were shown to have one of the fundamental attributes of life to adapt to environments according to Darwinian selection, and they are likely to be living fossils that have survived from the pre-cellular RNA world. In 50 years of research since their discovery, it was revealed that viroids invade host cells, replicate in nuclei or chloroplasts, and undergo nucleotide mutation in the process of adapting to new host environments. It was also demonstrated that structural motifs in viroid RNAs exert different levels of pathogenicity by interacting with various host factors. Despite their small size, the molecular mechanism of viroid pathogenicity turned out to be more complex than first thought.

Viroid replication: rolling-circles, enzymes and ribozymes

Viroids, due to their small size and lack of protein-coding capacity, must rely essentially on their hosts for replication. Intriguingly, viroids have evolved the ability to replicate in two cellular organella, the nucleus (family Pospiviroidae) and the chloroplast (family Avsunviroidae). Viroid replication proceeds through an RNA-based rolling-circle mechanism with three steps that, with some variations, operate in both polarity strands: i) synthesis of longer-than-unit strands catalyzed by either the nuclear RNA polymerase II or a nuclear-encoded chloroplastic RNA polymerase, in both instances redirected to transcribe RNA templates, ii) cleavage to unit-length, which in the family Avsunviroidae is mediated by hammerhead ribozymes embedded in both polarity strands, while in the family Pospiviroidae the oligomeric RNAs provide the proper conformation but not the catalytic activity, and iii) circularization. The host RNA polymerases, most likely assisted by additional host proteins, start transcription from specific sites, thus implying the existence of viroid promoters. Cleavage and ligation in the family Pospiviroidae is probably catalyzed by an RNase III-like enzyme and an RNA ligase able to circularize the resulting 5′ and 3′ termini. Whether a chloroplastic RNA ligase mediates circularization in the family Avsunviroidae, or this reaction is autocatalytic, remains an open issue.

Processing of nuclear viroids in vivo: an interplay between RNA conformations

Replication of viroids, small non-protein-coding plant pathogenic RNAs, entails reiterative transcription of their incoming single-stranded circular genomes, to which the (+) polarity is arbitrarily assigned, cleavage of the oligomeric strands of one or both polarities to unit-length, and ligation to circular RNAs. While cleavage in chloroplastic viroids (family Avsunviroidae) is mediated by hammerhead ribozymes, where and how cleavage of oligomeric (+) RNAs of nuclear viroids (family Pospiviroidae) occurs in vivo remains controversial. Previous in vitro data indicated that a hairpin capped by a GAAA tetraloop is the RNA motif directing cleavage and a loop E motif ligation. Here we have re-examined this question in vivo, taking advantage of earlier findings showing that dimeric viroid (+) RNAs of the family Pospiviroidae transgenically expressed in Arabidopsis thaliana are processed correctly. Using this methodology, we have mapped the processing site of three members of this family at equivalent positions of the hairpin I/double-stranded structure that the upper strand and flanking nucleotides of the central conserved region (CCR) can form. More specifically, from the effects of 16 mutations on Citrus exocortis viroid expressed transgenically in A. thaliana, we conclude that the substrate for in vivo cleavage is the conserved double-stranded structure, with hairpin I potentially facilitating the adoption of this structure, whereas ligation is determined by loop E and flanking nucleotides of the two CCR strands. These results have deep implications on the underlying mechanism of both processing reactions, which are most likely catalyzed by enzymes different from those generally assumed: cleavage by a member of the RNase III family, and ligation by an RNA ligase distinct from the only one characterized so far in plants, thus predicting the existence of at least a second plant RNA ligase.

Viroid: a useful model for studying the basic principles of infection and RNA biology

Viroids are small, circular, noncoding RNAs that currently are known to infect only plants. They also are the smallest self-replicating genetic units known. Without encoding proteins and requirement for helper viruses, these small RNAs contain all the information necessary to mediate intracellular trafficking and localization, replication, systemic trafficking, and pathogenicity. All or most of these functions likely result from direct interactions between distinct viroid RNA structural motifs and their cognate cellular factors. In this review, we discuss current knowledge of these RNA motifs and cellular factors. An emerging theme is that the structural simplicity, functional versatility, and experimental tractability of viroid RNAs make viroid-host interactions an excellent model to investigate the basic principles of infection and further the general mechanisms of RNA-templated replication, intracellular and intercellular RNA trafficking, and RNA-based regulation of gene expression. We anticipate that significant advances in understanding viroid-host interactions will be achieved through multifaceted secondary and tertiary RNA structural analyses in conjunction with genetic, biochemical, cellular, and molecular tools to characterize the RNA motifs and cellular factors associated with the processes leading to systemic infection.

Processing of linear longer-than-unit-length potato spindle tuber viroid RNAs into infectious monomeric circular molecules by a G-specific endoribonuclease

Different cDNA constructs were used for the in vitro synthesis of RNA transcripts that contain a complete monomeric unit of the potato spindle tuber viroid (PSTVd) plus an additional repeat of a part of the circular RNA genome. These permutated linear longer-than-unit-length PSTVd RNAs were incubated with the G-specific endoribonuclease RNase T1 which generated monomeric circular PSTVd RNA molecules that were infectious when mechanically inoculated to tomato plants. Besides the correct monomeric PSTVd RNA, smaller and larger circular RNAs were also formed during the reaction. The comparison of different transcripts revealed that correct in vitro processing of PSTVd RNA can proceed at alternative sites indicating that circularization is driven by RNA structure and not governed by a particular sequence. Based on these data, we propose a novel model for the processing of multimeric replicative viroid RNA intermediates through RNA cleavage and ligation catalyzed by a host endoribonuclease.

RNA progeny of an infectious two-base deletion cDNA mutant of potato spindle tuber viroid (PSTV) acquire two nucleotides in Planta

Deletion mutations were generated in four structural domains of a potato spindle tuber viroid (PSTV) complementary DNA (cDNA) clone. Deletions of 3 to 5 nucleotides at the central conserved domain (CCGGG, positions 94 to 98), variable domain (GCCG, positions 146 to 149) and pathogenicity domain (CGA, positions 286 to 288) abolished infectivity of dimeric or trimeric cDNA constructs, or their in vitro transcripts. By contrast, a clone (St4) with a deletion of two nucleotides (UU, positions 339 and 340), located at the left terminal domain, retained infectivity when DNA or in vitro transcribed (+)RNA was used as inoculum. Sequencing of four cDNA clones of such viroid progeny demonstrated that two nucleotides were added at the deletion site. Two of the viroid progeny contained a CG addition. A third clone possessed a GU addition, whereas the fourth clone had a UU addition which represents a true reversion to full-length wild-type PSTV RNA. Ribonuclease protection assay of viroid progeny from St4-infected tomato plants suggested that only a negligible proportion of the St4 progeny were true revertants.

The role of the viroid central conserved region in cDNA infectivity

The effect of sequence duplication upon the infectivity of plasmid DNAs containing monomeric tomato apical stunt viroid cDNAs has been determined. Two factors appear to control the specific infectivity of the different plasmid constructions tested: the presence of a subset of a palindromic sequence located within the central conserved region and the orientation of the viroid cDNA within the recombinant plasmid. Deletions which disrupt the integrity of the putative processing site abolished cDNA infectivity, a result that is consistent with the involvement of this site in the cleavage/ligation of viroid RNAs during replication.

Infectivity of chimeric viroid transcripts reveals the presence of alternative processing sites in potato spindle tuber viroid

In an investigation of viroid replication and pathogenesis, we have assessed the effect of sequence duplication of the upper central conserved region (CCR) of the molecule on the infectivity of RNAs transcribed in vitro from partial dimers of wild-type and mutant viroid cDNAs. In one set of experiments, the relative infectivities of one monomeric potato spindle tuber viroid (PSTV) and five oligomeric SP6 transcripts [PSTV or PSTV-TASV (tomato apical stunt viroid) chimeras] were compared. With one exception, the extent of sequence duplication in the CCR, and thus the length of the so-called palindrome, does correlate with an increase in specific infectivity. In a second set of experiments, in vitro generated site-specific mutations in cloned PSTV were used as markers to determine if a cleavage/ligation at sites other than the palindrome could generate infectious molecules in vivo. The creation of a novel PSTV-TPMV (tomato planta macho viroid) chimera in these experiments provides evidence that multimeric RNAs can be processed at sites other than the CCR to yield monomeric progeny.

Subviral pathogens of plants: the viroids

Research during the last 15 years has conclusively shown that viroids are not only fundamentally different from viruses at the molecular level, but that they are most likely not directly related to viruses in an evolutionary sense. Today, viroids are among the most thoroughly studied biological macromolecules. Their molecular structures have been elucidated to a large extent, but much needs to be learned regarding the correlation between molecular structure and biological function. The availability of the tools of recombinant DNA technology in viroid research promises rapid progress in these areas of inquiry.

Analysis of RNA structures by temperature-gradient gel electrophoresis: viroid replication and processing

The structure and structural transitions of single-stranded RNA were investigated by energy calculations and temperature-gradient gel electrophoresis. Most experiments have been carried out on RNA of mature viroids and their replication intermediates, which are RNA (-) strand oligomers and RNA (+) strand oligomers. The technique of temperature-gradient gel electrophoresis proved to be particularly useful for analysing co-existing structures. The secondary structure of lowest free energy for unit length and oligomeric replication intermediates is an extended rod-like structure similar to that of the mature circular viroid. When this structure is used as a model for calculations, there is a large degree of agreement between theoretical and experimental curves. Under particular solution conditions, however, (+) strand oligomers undergo a rearrangement from the extended structure to a branched structure, in which every two units form a region of three helices, together 28 bp long. This structure is called the tri-helical structure. The process of structure formation during the synthesis of oligomers could be followed: at first, a transient multi-branched structure is formed which is then transformed into the extended and the tri-helical structures. The region of the three stable helices serves to divide up the oligomeric (+) strand into structural units which may be recognized by cleavage and ligation enzymes, and be processed into circular mature viroids. Co-transcription of complementary (+) and (-) strands shows that energetically favored double-strand formation may at least partially be prohibited by stable secondary structures of the single strands. Natural replication intermediates have been analysed in respect to their subcellular location and their size distribution. They are associated with the nucleoli as was found earlier for mature viroids. Natural (-) strand oligomers are larger than (+) strand oligomers; both types show a periodicity in the size distribution of two units. The models of the structures, which are involved in viroid processing, are in accordance with recent infectivity data and with the results on natural replication intermediates.

Synthesis in vitro of infectious RNA copies of the virulent satellite of turnip crinkle virus

RNA copies, synthesized in vitro, of the virulent satellite (RNA C) of turnip crinkle virus (TCV) infect plants when coinoculated with helper virus RNA. RNA C is a small linear RNA of about 355 bases which intensifies TCV symptoms in infected plants. Full-length cDNA copies of the satellite were inserted in an expression vector (for RNA synthesis in vitro) in such a way that RNA synthesized in vitro had the same 5'-end as the native satellite. Plus-strand RNA copies of the satellite in near-monomer and multimer form infected plants, while minus-strand RNA copies and DNA copies of the satellite RNA did not do so under the conditions tested. When plants were inoculated with RNAs synthesized in vitro from two independently cloned satellite cDNAs with base sequence and length differences, the products of infection corresponded in sequence to the different cRNAs used in the inocula. Satellite RNAs synthesized in vitro from either cDNA produced the same symptoms as the native satellite RNA.